about
Adaptor protein self-assembly drives the control of a cullin-RING ubiquitin ligaseThe BTB domain, found primarily in zinc finger proteins, defines an evolutionarily conserved family that includes several developmentally regulated genes in DrosophilaCrystal structures of saposins A and CSolution structure and dynamics of the outer membrane enzyme PagP by NMR.Crystal structure of the BTB domain from the LRF/ZBTB7 transcriptional regulatorMechanism of SMRT corepressor recruitment by the BCL6 BTB domainStructure of a BCOR Corepressor Peptide in Complex with the BCL6 BTB Domain DimerStructures of the human ceramide activator protein saposin DProtecting role of cosolvents in protein denaturation by SDS: a structural studyCrystal structure of a self-assembling lipopeptide detergent at 1.20 A.A Small-Molecule Inhibitor of BCL6 Kills DLBCL Cells In Vitro and In VivoPagP Crystallized from SDS/Cosolvent Reveals the Route for Phospholipid Access to the Hydrocarbon RulerStructure of saposin A lipoprotein discsCrystal structure of GnsA from Escherichia coliStructural Insights into KCTD Protein Assembly and Cullin3 RecognitionStructure of Human Acid Sphingomyelinase Reveals the Role of the Saposin Domain in Activating Substrate HydrolysisGauging a hydrocarbon ruler by an intrinsic exciton probe.A hydrocarbon ruler measures palmitate in the enzymatic acylation of endotoxinAssessing the stability of membrane proteins to detect ligand binding using differential static light scattering.Critical residues within the BTB domain of PLZF and Bcl-6 modulate interaction with corepressors.Prostate cancer. Ubiquitylome analysis identifies dysregulation of effector substrates in SPOP-mutant prostate cancer.The BACK domain in BTB-kelch proteins.Characterizing the Size and Composition of Saposin A Lipoprotein Picodiscs.Molecular imaging of membrane interfaces reveals mode of beta-glucosidase activation by saposin C.Higher-order oligomerization promotes localization of SPOP to liquid nuclear speckles.Systemic ceramide accumulation leads to severe and varied pathological consequences.Detergent-mediated protein aggregation.The integrated landscape of driver genomic alterations in glioblastoma.Lipopeptide detergents for membrane protein studies.Screening Glycolipids Against Proteins in Vitro Using Picodiscs and Catch-and-Release Electrospray Ionization-Mass Spectrometry.PKA signaling drives mammary tumorigenesis through Src.A hybrid mechanism of action for BCL6 in B cells defined by formation of functionally distinct complexes at enhancers and promoters.Mutations in the Fusion Protein of Measles Virus That Confer Resistance to the Membrane Fusion Inhibitors Carbobenzoxy-d-Phe-l-Phe-Gly and 4-Nitro-2-Phenylacetyl Amino-Benzamide.The lactose permease meets Frankenstein.What's new with lactose permease.Crystal structure of O4-methyl uridine: stacking induced changes in the geometry of the pyrimidine ring and its mutagenic role.Insertion of carrier proteins into hydrophilic loops of the Escherichia coli lactose permease.Stability of the lactose permease in detergent solutions.Expression, purification, crystallization, and preliminary X-ray analysis of recombinant human saposin B.Refined structures of the ligand-binding domain of the aspartate receptor from Salmonella typhimurium.
P50
Q24336527-F32D5A66-CE55-473E-B0C5-63BAF9E2941CQ24562764-FA76956D-DA52-4957-8F1B-2AAC258E31BFQ24647618-D88FEF96-EF74-45B2-8702-D31B7E622488Q27639729-A88C264D-5BDA-4514-8EA3-FA987D13B10EQ27640942-18A63061-9481-48DD-9256-70B65FCA6424Q27642845-DC1E7D69-4CF7-4A3F-8353-FA393E177627Q27649873-07D929B8-E964-49ED-B0BD-0D5BB1AB1477Q27650509-CD344700-AC37-4A84-8CD4-2F1E510779E0Q27650741-6986A2E1-7CF2-490E-A9C7-EE8D01908BACQ27651824-7F8C7E5F-A1D3-4F85-B5DE-71C8705EFE0DQ27660498-94AF3F46-A950-4510-BC52-20191CB499EFQ27664381-F3E0DDEC-B309-4FF5-94F9-5D5EDC93E623Q27677107-A2EFCE37-6B38-45A5-9388-5AA3D75AAD35Q27700082-434F37E7-6D2F-4FE4-991F-9DD1DB6664A5Q27702091-C26D5EE1-8C07-4628-B965-F76B80E4AFF9Q27714351-F275EF56-F511-4D96-9B1D-0261AC31420EQ30158021-D1B9B468-C806-49ED-8471-1D39E46D7CC4Q30163924-30D2AEDE-3C55-4A1C-9CCB-FD56842A45A2Q33530831-3A3AEE56-E4EF-4794-A36A-B01049AA64FFQ34324111-0675DCED-5044-4B33-94A3-0854FF07887CQ34637940-0E8244CE-35CB-4CEC-A866-EABDB5F80F42Q35950674-1811CC96-EFFD-44FF-9C35-726550A00C1BQ36105679-BED2E097-AEB2-4E8E-AED0-87E8BB2FAE22Q36141456-7CC832C1-9063-4585-AFEB-C0ED15F8BB67Q37011857-9A9B95D0-E6EC-4133-87C5-A8945D47EAE1Q37188558-9D0E0050-810F-475A-A055-F8E1AD677C7FQ37222622-81E8BD08-2895-4826-AD2E-880102B40465Q37237987-D6BBDB34-BFA1-4BAA-A266-2E6418F48E28Q37580277-A30C55F6-43FB-4121-89C9-3E14C61E91EBQ38292960-F0F649E7-DBE3-4A4E-AE8F-39CC42E2EA57Q39012308-D0F36808-1CB0-45C1-A34E-FEE090B496B2Q39116273-A6500F65-C6C2-4F11-BB9B-B758417E80D3Q40042437-F526A04E-FF93-43D8-9A00-ED8831A6416DQ40570478-D996D422-82DF-4817-914A-5C57F34A9B2DQ40734067-8C2F99E5-69A9-4179-B715-12E9D6560B32Q42248255-21BD9187-D0E7-4EA5-A7F8-DC95A08BADE6Q44052383-9ECBAB91-48CB-49ED-8605-78F81113D776Q44052387-2D9B99F2-1BF9-4D1F-9E0F-4DDA4E36E856Q44268108-E51C7584-2724-456A-8D43-F6AD6242D193Q46345020-A26BD929-D093-4219-95AD-D1A4C9D82BF9
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Gilbert G Privé
@ast
Gilbert G Privé
@en
Gilbert G Privé
@es
Gilbert G Privé
@nl
type
label
Gilbert G Privé
@ast
Gilbert G Privé
@en
Gilbert G Privé
@es
Gilbert G Privé
@nl
prefLabel
Gilbert G Privé
@ast
Gilbert G Privé
@en
Gilbert G Privé
@es
Gilbert G Privé
@nl
P106
P31
P496
0000-0002-0712-4319